Effect of oat's soluble fibre (β-glucan) as a fat replacer on physical, chemical, microbiological and sensory properties of low-fat beef patties

This study evaluated the effect of adding oat fibre source of β-glucan (13.45%) on physical, chemical, microbiological and sensory traits of low-fat (<10%) beef patties as compared to 20% fat control patties. Significant (p<0.05) improvements in cooking yield (74.19%), and retentions of fat (79.74%) and moisture (48.41%) of low-fat patties were attributed to the water binding ability of β-glucan. Because of larger water retentions moisture contents of raw and cooked low-fat patties were higher (p<0.05) than those of the control patties. Cholesterol content was similar across formulations. Low-fat and control beef patties remained stable in microbiological quality during 60days frozen storage. Low-fat patties were found to be of lower degree of likeness in the taste but juicer than control (p<0.05). Besides appearance, tenderness and colour were not affected by the addition of oat's soluble fibre. Oat fibre can be used successfully as a fat substitute in low-fat beef patties.     

Fat Level and Freezing Temperature Affect Sensory, Shear, Cooking and Compositional Properties of Ground Beef Patties

Experiments were conducted to determine effects of two targeted fat levels (6, 20%) and two freezing temperatures (?43, ?20°C) on sensory, shear, cooking and compositional properties of beef patties. Select grade beef rounds (IMPS 161) were used as the lean source for patties with U.S. Choice plates as the fat source. The 20% fat formulation had increased beef flavor and initial tenderness (?20°C frozen patties only) scores, but had higher instrumental shear values compared to the 6% fat patties. Freezing patties (especially those of 6% fat) at ?43°C greatly improved sensory and instrumental tenderness. Faster freezing reduced fat retention of 20% fat patties during cooking. Use of Select grade beef rounds coupled with rapid freezing is suggested for producing acceptable low-fat ground beef patties.     

Properties of Low-Fat Ground Beef Containing Potassium Lactate During Aerobic Refrigerated Storage

Low-fat patties containing water, carrageenan, encapsulated salt and hydrolyzed vegetable protein (carrageenan-based patties) with 0, 1, 2 or 3% potassium lactate were compared to low-fat all-beef patties with no additives. Carrageenan-based patties had enhanced (P<0.05) sensory properties (juiciness, tenderness, mealiness and beef flavor intensity) compared to all-beef patties. The bacterial populations of low-fat, carrageenan-based patties did not differ (P<0.05) from low-fat all-beef patties. Bacterial growth in low-fat, carrageenan-based patties was reduced through the use of 2 or 3% potassium lactate with no deleterious effects on the sensory properties of the low-fat, ground beef. However, low-fat, carrageenan-based patties underwent greater (P<0.5) discoloration and lipid oxidation during aerobic refrigerated storage than all-beef patties.     

Sodium Alginate Plus Modified Tapioca Starch Improves Properties of Low-Fat Beef Patties

Sodium alginate (A) in combination with modified tapioca starch (T) was evaluated in low-fat beef patties cooked by broiling or grilling to 68 or 74°C. Added water was used with AT formulations at 7% (AT7) or 14% (AT14) levels. In comparisons with all-beef patties (8 and 20% fat), AT provided improvements in tenderness, juiciness and cooking yields without increasing fat retention or affecting beef flavor. In sensory comparisons with 14 commercially processed, low-fat beef patties, AT7 and 14 patties received the highest ratings. Combined use of A and T would provide improved acceptability of low-fat patties over that from using single fat replacers.     

Textural and Physicochemical Properties of Low-Fat, Precooked Ground Beef Patties Containing Carrageenan and Sodium Alginate

Textural and physicochemical characteristics of selected hydrocolloids incorporated into low-fat, precooked, beef patties were investigated. Patties with an alginate/carrageenan combination had higher yields and percent moisture but lower shear force values than those of alginate or carrageenan treatments within the same fat level. Alginate appeared to improve texture slightly more than carrageenan, but carrageenan tended to release more free water after cooking and reheating. Patties with 10% fat were generally lower in shear value, cooking yield and percentage free water released as compared to their 5% fat counterparts with the same added ingredient. Low-fat, precooked, ground beef patties containing alginate/carrageenan combinations were comparable to regular beef patties (20% fat control) regarding yields and textural properties.     

超高压技术辅助优化牛皮胶原低脂牛肉饼工艺

以超高压技术辅助制备的牛皮胶原为脂肪替代物,制作低脂牛肉饼.结合质构、烹饪损失和感官评分结果,探究超高压压力(200、250、300、350、400 MPa)、超高压时间(5、10、15、20、25 min)、NaCl添加量(1％、1.3％、1.5％、1.7％、1.9％,质量分数)和复合磷酸盐添加量(0.1％、0.2％...     

Low Fat Level Effects on Sensory, Shear, Cooking, and Chemical Properties of Ground Beef Patties

Two experiments were conducted to determine the effects of targeted fat level (0, 4, 8, 12, 16, 20%) on sensory, shear, cooking and chemical properties of ground beef patties. Frozen patties from all fat levels were cooked to achieve similar cooking yields. As fat levels decreased, tenderness, juiciness and flavor ratings decreased and shear force increased, with more pronounced differences at lower fat levels. Patties processed with 0% fat were rated lower in juiciness and flavor compared to all other fat levels. These studies suggested that alterations in processing and cooking would probably be necessary to achieve acceptance of extremely low-fat beef patties.     

NONMEAT INGREDIENTS FOR LOW-FAT GROUND BEEF PATTIES

Nine ground beef treatments were evaluated to compare chemical, physical and sensory characteristics of low-fat ground beef patties containing various water binders. Treatments 1–5 contained a blend of iota and kappa carrageenans having various viscosity and gelling characteristics (SD389, Viscarin SD 389; ME389, Viscarin ME 389; GP379, Gelcarin GP379; ME389/GP379, 50/50 ME389 & GP379; and ME621, Gelcarin ME621), and treatments 6–9 contained other water binders (XG/LBG, xanthan/locust bean gum; PF, pea flour; ALG, algin; and LB. Lean Bind^TMmodified food starch). Treatment 1, which contained carrageenan (SD389), served as the control. Algin patties were rated lowest in flavor intensity. Algin and LB patties were highest in sensory tenderness and had the lowest shear force values. The patties manufactured from ME389/GP379 and XG/LBG received higher overall acceptability scores than the control SD389 patties.     

THE INFLUENCE OF SALT AND HYDROLYZED VEGETABLE PROTEIN ON THE SENSORY ATTRIBUTES OF GROUND COW BEEF PATTIES

Ground cow beef was formulated to contain NaCl (0%, 1% or 2%) and hydrolyzed vegetable protein (0%, 0.25%, 0.50% or 0.75%) and was made into patties. Cow beef and steer beef patties without salt or HVP were utilized as controls. Patties were evaluated for fat and moisture content and sensory attributes. Meat source had no significant effect on fat and moisture content or on sensory attributes. The addition of NaCl resulted in patties that were more juicy, more tender and more desirable in flavor and texture than the control patties. Sensory ratings increased as the level of added salt increased. Patties containing 0.25% hydrolyzed vegetable protein were more tender, more juicy and received higher texture and flavor desirability ratings than patties containing 0%, 0.50% or 0.75% hydrolyzed vegetable protein.     

Fat Level, High Temperature Cooking and Degree of Doneness Affect Sensory, Chemical and Physical Properties of Beef Patties

Ground beef patties containing either 4 or 20% fat were cooked by electric grill (G) alone or in combination with overhead broiler unit (BG) to be (visually) either medium or well-done. Patties with 20% fat had higher beef flavor intensity, juiciness and tenderness scores, lower Instron shear and compression values, and lower cooking yields than 4% fat patties. However, 4% fat patties cooked to medium, had similar sensory ratings to 20% fat patties cooked well-done. About 20% of patties cooked to medium did not reach recommended internal temperatures and holding times for food safety.     

Storage Stability of Low-fat Ground Beef Made with Lower Value Cuts of Beef

Five combinations of low-fat ground beef treatments were prepared with lower value raw-materials: 90% lean cow trimmings, 50/50 Choice trimmings, 95% lean Choice trimmings, defatted clods and rounds, cow knuckles, and cow chucks. They were compared to a 20% fat control for quality attributes during 24 wk frozen (?20°C) storage. Control patties had greater (P<0.05) cooking loss, shear force, and connective tissue, and lower (P<0.05) juiciness scores than low-fat treatments. All low-fat pattie treatments were rated higher (P<0.05) in flavor intensity than control patties. Low-fat patties manufactured with a majority of lean cow trimmings had a greater color (pigment) and oxidative (lipid) stability.     

Inclusion of blended lipid solutions as functional ingredients to alter the fatty acid profile of beef patties

Beef patties formulated to contain beef fat, plant oil, and a rosemary extract to increase unsaturated fatty acid content and maintain desirable sensory attributes were compared to control beef patties formulated without plant oils. Treatment patties were formulated to a fat content of 10% or 20% by combining beef trimmings (6% fat) with 4% or 14% addition of a lipid blend. Blends contained 57% beef tallow, 0.3% rosemary extract, and 43% of high oleic safflower oil (SO), olive oil (OO), or corn oil (CO). Lipid oxidation, as measured by TBA values, of treatment patties were similar to control patties after 0 and 3 d of refrigerated (2 °C) storage and up to 56 d of frozen (-10 °C) storage. Cooked lipid blend patties having a fat content of 10% or 20% were similar to or higher than control patties for juiciness and were no different for other sensory attributes evaluated. At fat levels of 10% or 20%, oleic acid (18: 1) in cooked SO patties (46.1% and 50.3%, respectively) and OO patties (43.8% and 48.1%, respectively) was higher than the control (37.3% and 37.6%, respectively). Unsaturated to saturated fatty acid ratios at the 10% or 20% fat levels were higher in SO (1.37 and 1.60, respectively) and CO (1.40 and 1.48, respectively) patties than the control (0.97 and 0.94, respectively). Beef patties manufactured with varying lipid blends increased unsaturated fatty acid content and were similar in physical characteristics and sensory attributes of all beef patties formulated without lipid blends. PRACTICAL APPLICATION: The development of healthier beef products that will be more appealing to consumers has long been an industry goal. The authors believe that lipid blends such as the one used in this study could be used to create such products, not only in the form of beef patties, but any number of processed meat products. Because the materials and equipment used to create the lipid blends in this study are widely available, their incorporation into meat products would represent a small capital investment. This is an important factor in bringing a reasonably priced, healthier product to consumers.     

Low-Fat Ground Beef from Desinewed Shanks With Reincorporation of Processed Sinew

Six shank treatments (one at 7% and five at 10% fat) and two ground round controls (10 and 20% fat) were used to compare sensory properties of low-fat ground beef from shanks with and without sinew reincorporated. Five shank treatments were desinewed with a commercial de-sinewer; the other was whole ground shank. Four desinewed shank treatments had 7% flaked sinew reincorporated; the fifth had none. Patties with flaked sinew had more (P < 0.05) collagen than controls or those with desinewed shank only. Control patties had lower pH (P < 0.05) than shank patties (5.80 vs 6.07). Desinewed-shank patties had fewer (P < 0.05) connective tissue particles and were more (P < 0.05) juicy than whole-ground-shank patties. Shank patties were lighter red but less stable in color than the controls.     

Effect of grind size and fat levels on the physico-chemical and sensory characteristics of low-fat ground buffalo meat patties

Two experiments were carried out to investigate the influence of grind size (3, 4 or 6 mm) and fat levels (6, 8, 10 or 20%) on the physico-chemical and sensory characteristics of low-fat ground buffalo meat patties prepared using a combination of carrageenan (0.5%) and sodium alginate (0.1%). At a constant fat level of nearly 8%, there was no significant difference (P>0.05) in the cooking yield, pH, proximate composition and dimensional changes of patties prepared at different grind sizes. However, shear force value increased significantly (P<0.05) with an increase in grind size. The sensory scores were significantly (P<0.05) higher for patties prepared using 3 mm grind size as compared to those prepared at 4 and 6 mm grind sizes and hence it was adopted as the optimum grind size for low-fat ground buffalo meat patties. At a constant grind size of 3mm, cooking yield, moisture, protein and gain in height were significantly (P<0.05) higher and shear force values were significantly (P<0.05) lower for patties at all low-fat levels as compared to the control with 20% fat. Based on its significantly higher (P<0.05) sensory scores, 10% fat level was selected as optimum for low-fat ground buffalo meat patties, although even at 8% fat level sensory rating remained between good to very good.     

Sensory evaluation of beef patties and sausages containing lipids with various component fatty acids

Sensory scores of beef patties and emulsion-type sausages containing varying levels of lipids with various component fatty acids were investigated. Sensory scores of beef patties containing solid fat were relatively constant at every fat level examined. However, scores of beef patties containing liquid oil decreased with increasing level of added oil. In the case of sausages, on the other hand, sensory evaluation scores markedly decreased with increasing the level of solid fat, while no significant change was observed in panel scores when liquid oil was mixed into sausages. Even 10% level of added lipids satisfactorily gave preferable acceptability to beef patties and sausages.     

Enhancement of the nutritional status of beef patties by adding flaxseed flour

Flaxseed flour was used as a functional ingredient in the production of beef patties. Beef patties were produced with five different formulations; the addition of 3%, 6%, 9%, 12% and 15% flaxseed flour. Control samples were formulated with 10% and 20% fat addition. Raw and cooked beef patties were analyzed for moisture, protein, fat, ash, pH, color parameters and fatty acid profiles. Beef patties were evaluated for cooking loss and sensory properties. Fat and ash content of raw patties increased, while moisture and protein content decreased with increased flaxseed flour. The same trend (except fat content) was also observed after cooking. The addition of flaxseed flour did not affect pH values of raw and cooked beef patties. The addition of flaxseed flour improved the cooking loss but, increased the energy value (as kcal/100 g). L and a values of raw beef patties containing flaxseed flour were close to controls with 10% fat. α-linolenic acid content of raw and cooked beef patties increased as the level of flaxseed flour increased. The PUFA/SFA ratio increased from 0.04 in the control with 10% fat to 0.62 in the raw beef patties with 15% flaxseed flour. The n-6/n-3 ratio decreased from 5.76 in the control with 10% fat to 0.36 in the raw beef patties with 15% flaxseed flour. The nutritional status of beef patties was enhanced with minimal composition and sensory changes with 3% or 6% flaxseed flour addition.     

Use of electrical stimulation, hot processing and carrageenan for processing low-fat ground beef patties

Three studies were conducted to determine the effects of electrical stimulation, hot processing and carrageenan usage on sensory, shear force and cooking properties of low-fat (5, 10%) beef patties. The right or left sides of beef carcasses assigned to electrical stimulation (ES) received 600 V pulsating current for 120 s. Non-stimulated (NS) sides were also included for comparisons. Sides subjected to hot processing (HP) were boned 90 min post-exsanguination. Cold processing (CP) was initiated 48 h post mortem. Formulations for the manufacture of patties included the use of carrageenan [none, 0.5% iota (ι), 0.5% kappa (κ)]. Patties from NSHP beef had higher pH and cooking yields, less shrink in patty dimensions during cooking and lower shear force values than patties from NSCP controls (P < 0.05). ES improved tenderness and juiciness of CP patties, while ESHP patties exhibited higher cooking yields than NSCP patties. Tenderness was improved in two of the three studies as a result of increasing the fat content from 5 to 10%. Use of ι-carrageenan provided improvements in tenderness and juiciness over patties receiving no carrageenan or κ-carrageenan. Processors should consider HP with 1.0% added salt (improved cooking yields, patty configuration, tenderness) and the use of ι-carrageenan (improved tenderness and juiciness) for low-fat beef patties.     

Effect of Mixture and Storage on the Palatability of Beef-Turkey Patties

Beef and turkey mixtures were formulated to contain 100/0, 80/20, 60/40, 40/60, 20/80 or 0/100% lean beef/lean turkey with a constant fat content. Sensory parameters and physical characteristics were measured to evaluate the product during storage. There were no differences (p>0.05) in beef flavor between 80% and 100% beef products or between 0%, 20%, 40% and 60% beef patties. Juiciness scores were increased by adding turkey while texture scores were decreased. Similarly, 80% and 100% beef patties had greater (p<0.05) hardness than other mixtures. Off-flavor scores were not affected by mixture although malonaldehyde content of cooked patties increased markedly as the percentage of turkey increased. In general, ground beef products containing between 20% to 80% turkey had similar sensory, storage and physical characteristics.     

MODIFIED PREGELATINIZED POTATO STARCH IN LOW-FAT GROUND BEEF PATTIES

Effects of modified pregelatinized potato starch (MPPS) in 5 and 20% fat ground beef patties were evaluated. In formulas containing starch, MPPS comprised 3.0% and added water 5.0% of the raw mixture. Use of 20% rather than 5% fat in the ground beef improved sensory tenderness measured early in chewing, while lowering many Instron measurements. The 20% fat patties had more intense beef flavor. MPPS increased tenderness, but reduced juiciness and beef flavor. The addition (1% of formulation) of concentrated butter flavor to ground beef with MPPS produced beef flavor equivalent to all-beef patties. The use of MPPS increased cooking yields and moisture content following cooking and reduced fat retention of 20% patties. MPPS increased heating rate while retaining substantial moisture during cooking. Inclusion of MPPS in beef patty formulations offers improvements in tenderness and cooking yield, while reducing fat retention during cooking.     

Fat, Soy and Carrageenan Effects on Sensory and Physical Characteristics of Ground Beef Patties

Sensory and physical characteristics of beef patties containing 20% fat, 8% fat, or 8% fat plus 20% soy protein isolate (SI), soy flour (SF), soy concentrate (SC), or a mixture (MIX) of carrageenan (0.5%), starch (0.5%), and phosphate (0.2%) were compared after 0, 4, 8, and 12 wks storage at - 18°C. MIX had higher Hunter a* values than other treatments. Cook loss was lowest for MIX and highest for all beef patties. Soy extenders decreased beefy flavor and increased off-flavor scores. Time in frozen storage increased off-flavor, rubbery texture, and TBA value, and decreased red color and Hunter b* value of ground beef patties. Quality may be lowered in frozen-stored high fat, or low-fat-soy extended beef patties.